390 likes | 597 Views
Chapter 4. Linked Lists. Preliminaries. Options for implementing an ADT List Array has a fixed size Data must be shifted during insertions and deletions Linked list is able to grow in size as needed Does not require the shifting of items during insertions and deletions. Preliminaries.
E N D
Chapter 4 Linked Lists
Preliminaries • Options for implementing an ADT List • Array has a fixed size • Data must be shifted during insertions and deletions • Linked list is able to grow in size as needed • Does not require the shifting of items during insertions and deletions © 2005 Pearson Addison-Wesley. All rights reserved
Preliminaries Figure 4.1 a) A linked list of integers; b) insertion; c) deletion © 2005 Pearson Addison-Wesley. All rights reserved
Pointers • A pointer contains the location, or address in memory, of a memory cell • Initially undefined, but not NULL • A statically allocated pointer declaration int *p; • A dynamically allocated pointer variable p = new int; © 2005 Pearson Addison-Wesley. All rights reserved
Pointers • The expression, *p, denotes the memory cell to which ppoints • The & address-of operator places the address of a variable into a pointer variable • p = &x; Figure 4.2A pointer to an integer © 2005 Pearson Addison-Wesley. All rights reserved
Pointers • The delete operator returns dynamically allocated memory to the system for reuse, and leaves the variable undefined • delete p; • A pointer to a deallocated memory cell is possible and dangerous • Assign the pointer q the value in p q = p; © 2005 Pearson Addison-Wesley. All rights reserved
Pointers Figure 4.3(a) declaring pointer variables; (b) pointing to statically allocating memory; (c) assigning a value; (d) allocating memory dynamically; (e) assigning a value © 2005 Pearson Addison-Wesley. All rights reserved
Pointers Figure 4.3 (f) copying a pointer; (g) allocating memory dynamically and assigning a value; (h) assigning NULL to a pointer variable; (i) deallocating memory © 2005 Pearson Addison-Wesley. All rights reserved
Dynamic Allocation of Arrays • Use the new operator to allocate an array dynamically • An array name is a pointer to the array’s first element • The size of a dynamically allocated array can be increased double* oldArray = anArray; anArray = newdouble[2*arraySize]; © 2005 Pearson Addison-Wesley. All rights reserved
Pointer-Based Linked Lists • A node in a linked list is usually a struct struct Node { int item Node *next; }; //end struct • A node is dynamically allocated Node *p; p = new Node; Figure 4.6A node © 2005 Pearson Addison-Wesley. All rights reserved
Pointer-Based Linked Lists • The head pointer points to the first node in a linked list • If head is NULL, the linked list is empty • Executing the statement the statement head=new Node before head=NULL will result in a lost cell © 2005 Pearson Addison-Wesley. All rights reserved
Pointer-Based Linked Lists Figure 4.7 A head pointer to a list Figure 4.8A lost cell © 2005 Pearson Addison-Wesley. All rights reserved
Displaying the Contents of a Linked List • Reference a node member with the -> operator p->item; • A traverse operation visits each node in the linked list • A pointer variable cur keeps track of the current node for (Node *cur = head; cur != NULL; cur = cur->next) cout << cur->item << endl; © 2005 Pearson Addison-Wesley. All rights reserved
Displaying the Contents of a Linked List Figure 4.9 The effect of the assignment cur = cur->next © 2005 Pearson Addison-Wesley. All rights reserved
Deleting a Specified Node from a Linked List • Deleting an interior node prev->next=cur->next; • Deleting the first node head=head->next; • Return deleted node to system cur->next = NULL; delete cur; cur=NULL; © 2005 Pearson Addison-Wesley. All rights reserved
Deleting a Specified Node from a Linked List Figure 4.10 Deleting a node from a linked list Figure 4.11 Deleting the first node © 2005 Pearson Addison-Wesley. All rights reserved
Inserting a Node into a Specified Position of a Linked List • To insert a node between two nodes newPtr->next = cur; prev->next = newPtr; Figure 4.12 Inserting a new node into a linked list © 2005 Pearson Addison-Wesley. All rights reserved
Inserting a Node into a Specified Position of a Linked List • To insert a node at the beginning of a linked list newPtr->next = head; head = newPtr; Figure 4.13 Inserting at the beginning of a linked list © 2005 Pearson Addison-Wesley. All rights reserved
Inserting a Node into a Specified Position of a Linked List • Inserting at the end of a linked list is not a special case if cur is NULL newPtr->next = cur; prev->next = newPtr; Figure 4.14 Inserting at the end of a linked list © 2005 Pearson Addison-Wesley. All rights reserved
Inserting a Node into a Specified Position of a Linked List • Determining the point of insertion or deletion for a sorted linked list of objects for(prev = NULL, cur= head; (cur != null)&& (newValue > cur->item); prev = cur, cur = cur->next; © 2005 Pearson Addison-Wesley. All rights reserved
Public methods isEmpty getLength insert remove retrieve Private method find Private Data Members head Size Local variables to member functions cur prev A Pointer-Based Implementation of the ADT List © 2005 Pearson Addison-Wesley. All rights reserved
Constructors and Destructors • Default constructor initializes size and head • Copy constructor allows a deep copy • Copies the array of list items and the number of items • A destructor is required for dynamically allocated memory © 2005 Pearson Addison-Wesley. All rights reserved
Comparing Array-Based and Pointer-Based Implementations • Size • Increasing the size of a resizable array can waste storage and time • Storage requirements • Array-based implementations require less memory than a pointer-based ones © 2005 Pearson Addison-Wesley. All rights reserved
Comparing Array-Based and Pointer-Based Implementations • Access time • Array-based: constant access time • Pointer-based: the time to access the ith node depends on i • Insertion and deletions • Array-based: require shifting of data • Pointer-based: require a list traversal © 2005 Pearson Addison-Wesley. All rights reserved
Saving and Restoring a Linked List by Using a File • Use an external file to preserve the list between runs • Do not write pointers to a file, only data • Recreate the list from the file by placing each item at the end of the list • Use a tail pointer to facilitate adding nodes to the end of the list • Treat the first insertion as a special case by setting the tail to head © 2005 Pearson Addison-Wesley. All rights reserved
Passing a Linked List to a Function • A function with access to a linked list’s head pointer has access to the entire list • Pass the head pointer to a function as a reference argument Figure 4.22A head pointer as a value argument © 2005 Pearson Addison-Wesley. All rights reserved
Processing Linked Lists Recursively • Recursive strategy to display a list • Write the first node of the list • Write the list minus its first node • Recursive strategies to display a list backward • writeListBackward strategy • Write the last node of the list • Write the list minus its last node backward © 2005 Pearson Addison-Wesley. All rights reserved
Processing Linked Lists Recursively • writeListBackward2 strategy • Write the list minus its first node backward • Write the first node of the list • Recursive view of a sorted linked list • The linked list to which head points is a sorted list if • head is NULLor • head->next is NULLor • head->item < head->next->item, and head->next points to a sorted linked list © 2005 Pearson Addison-Wesley. All rights reserved
Objects as Linked List Data • Data in a linked list node can be an instance of a class typedefClassName ItemType; struct Node { ItemType item; Node *next; }; //end struct Node *head; © 2005 Pearson Addison-Wesley. All rights reserved
Circular Linked Lists • Last node references the first node • Every node has a successor • No node in a circular linked list contains NULL Figure 4.25 A circular linked list © 2005 Pearson Addison-Wesley. All rights reserved
Dummy Head Nodes • Dummy head node • Always present, even when the linked list is empty • Insertion and deletion algorithms initialize prev to reference the dummy head node, rather than NULL Figure 4.27 A dummy head node © 2005 Pearson Addison-Wesley. All rights reserved
Doubly Linked Lists • Each node points to both its predecessor and its successor • Circular doubly linked list • precede pointer of the dummy head node points to the last node • next reference of the last node points to the dummy head node • No special cases for insertions and deletions © 2005 Pearson Addison-Wesley. All rights reserved
Doubly Linked Lists Figure 4.29 (a) A circular doubly linked list with a dummy head node (b) An empty list with a dummy head node © 2005 Pearson Addison-Wesley. All rights reserved
Doubly Linked Lists • To delete the node to which curpoints (cur->precede)->next = cur->next; (cur->next)->precede = cur->precede; • To insert a new node pointed to by newPtr before the node pointed to by cur newPtr->next = cur; newPtr->precede = cur->precede; cur->precede = newPtr; newPtr->precede->next = newPtr; © 2005 Pearson Addison-Wesley. All rights reserved
Application: Maintaining an Inventory • Operations on the inventory • List the inventory in alphabetical order by title (L command) • Find the inventory item associated with title (I, M, D, O, and S commands) • Replace the inventory item associated with a title (M, D, R, and S commands) • Insert new inventory items (A and D commands) © 2005 Pearson Addison-Wesley. All rights reserved
The C++ Standard Template Library • The STL contains class templates for some common ADTs, including the list class • The STL provides support for predefined ADTs through three basic items • Containers are objects that hold other objects • Algorithms act on containers • Iterators provide a way to cycle through the contents of a container © 2005 Pearson Addison-Wesley. All rights reserved
Summary • The C++ new and delete operators enable memory to be dynamically allocated and recycled • Each pointer in a linked list is a pointer to the next node in the list • Array-based lists use an implicit ordering scheme; pointer-based lists use an explicit ordering scheme © 2005 Pearson Addison-Wesley. All rights reserved
Summary • Algorithms for insertions and deletions in a linked list involve traversing the list and performing pointer changes • Inserting a node at the beginning of a list and deleting the first node of a list are special cases • A class that allocates memory dynamically needs an explicit copy constructor and destructor © 2005 Pearson Addison-Wesley. All rights reserved
Summary • Recursion can be used to perform operations on a linked list • In a circular linked list, the last node points to the first node • Dummy head nodes eliminate the special cases for insertion into and deletion from the beginning of a linked list © 2005 Pearson Addison-Wesley. All rights reserved